In a power semiconductor module, the 0.2% yield strength of solder under a lead terminal that bonds the lead terminal and a semiconductor element is set to be lower than the 0.2% yield strength of solder under the semiconductor element that bonds the semiconductor element and an insulating substrate. As a result, the lead terminal is expanded with self-heating by energization of the semiconductor element, and stress is applied to the semiconductor element via the solder under the lead terminal. However, the solder under the lead terminal with low 0.2% yield strength reduces the stress that is applied to the semiconductor element. Thus, the reliability of a surface electrode of the semiconductor element that is bonded to the solder under the lead terminal is improved.

In a power semiconductor module, the 0.2% yield strength of solder under a lead terminal that bonds the lead terminal and a semiconductor element is set to be lower than the 0.2% yield strength of solder under the semiconductor element that bonds the semiconductor element and an insulating substrate. As a result, the lead terminal is expanded with self-heating by energization of the semiconductor element, and stress is applied to the semiconductor element via the solder under the lead terminal. However, the solder under the lead terminal with low 0.2% yield strength reduces the stress that is applied to the semiconductor element. Thus, the reliability of a surface electrode of the semiconductor element that is bonded to the solder under the lead terminal is improved.

A semiconductor device in which a semiconductor element mounted on a laminate substrate and an electrically conductive connection member are sealed with a sealing material, includes: a primer layer in an interface between the sealing material and sealed members including the laminate substrate, the semiconductor element, and the electrically conductive connection member, in which the sealing material includes a first sealing layer which is provided in contact with the primer layer; and a second sealing layer which covers the first sealing layer, the semiconductor device satisfies α.sub.p≥α.sub.1>α.sub.2 in which α.sub.p, α.sub.1, and α.sub.2 represent coefficients of linear thermal expansion of the primer layer, the first sealing layer, and the second sealing layer, respectively, α.sub.c≥15×10.sup.−6/° C. in which α.sub.c represents a composite coefficient of linear thermal expansion of the sealing layers, and E.sub.c≥5 GPa or more in which E.sub.c represents a composite Young's modulus of the sealing layers.

A semiconductor device in which a semiconductor element mounted on a laminate substrate and an electrically conductive connection member are sealed with a sealing material, includes: a primer layer in an interface between the sealing material and sealed members including the laminate substrate, the semiconductor element, and the electrically conductive connection member, in which the sealing material includes a first sealing layer which is provided in contact with the primer layer; and a second sealing layer which covers the first sealing layer, the semiconductor device satisfies α.sub.p≥α.sub.1>α.sub.2 in which α.sub.p, α.sub.1, and α.sub.2 represent coefficients of linear thermal expansion of the primer layer, the first sealing layer, and the second sealing layer, respectively, α.sub.c≥15×10.sup.−6/° C. in which α.sub.c represents a composite coefficient of linear thermal expansion of the sealing layers, and E.sub.c≥5 GPa or more in which E.sub.c represents a composite Young's modulus of the sealing layers.

A semiconductor device in which a semiconductor element mounted on a laminate substrate and an electrically conductive connection member are sealed with a sealing material, includes: a primer layer in an interface between the sealing material and sealed members including the laminate substrate, the semiconductor element, and the electrically conductive connection member, in which the sealing material includes a first sealing layer which is provided in contact with the primer layer; and a second sealing layer which covers the first sealing layer, the semiconductor device satisfies α.sub.p≥α.sub.1>α.sub.2 in which α.sub.p, α.sub.1, and α.sub.2 represent coefficients of linear thermal expansion of the primer layer, the first sealing layer, and the second sealing layer, respectively, α.sub.c≥15×10.sup.−6/° C. in which α.sub.c represents a composite coefficient of linear thermal expansion of the sealing layers, and E.sub.c≥5 GPa or more in which E.sub.c represents a composite Young's modulus of the sealing layers.

A semiconductor device in which a semiconductor element mounted on a laminate substrate and an electrically conductive connection member are sealed with a sealing material, includes: a primer layer in an interface between the sealing material and sealed members including the laminate substrate, the semiconductor element, and the electrically conductive connection member, in which the sealing material includes a first sealing layer which is provided in contact with the primer layer; and a second sealing layer which covers the first sealing layer, the semiconductor device satisfies α.sub.p≥α.sub.1>α.sub.2 in which α.sub.p, α.sub.1, and α.sub.2 represent coefficients of linear thermal expansion of the primer layer, the first sealing layer, and the second sealing layer, respectively, α.sub.c≥15×10.sup.−6/° C. in which α.sub.c represents a composite coefficient of linear thermal expansion of the sealing layers, and E.sub.c≥5 GPa or more in which E.sub.c represents a composite Young's modulus of the sealing layers.

In a power semiconductor module, the 0.2% yield strength of solder under a lead terminal that bonds the lead terminal and a semiconductor element is set to be lower than the 0.2% yield strength of solder under the semiconductor element that bonds the semiconductor element and an insulating substrate. As a result, the lead terminal is expanded with self-heating by energization of the semiconductor element, and stress is applied to the semiconductor element via the solder under the lead terminal. However, the solder under the lead terminal with low 0.2% yield strength reduces the stress that is applied to the semiconductor element. Thus, the reliability of a surface electrode of the semiconductor element that is bonded to the solder under the lead terminal is improved.

In a power semiconductor module, the 0.2% yield strength of solder under a lead terminal that bonds the lead terminal and a semiconductor element is set to be lower than the 0.2% yield strength of solder under the semiconductor element that bonds the semiconductor element and an insulating substrate. As a result, the lead terminal is expanded with self-heating by energization of the semiconductor element, and stress is applied to the semiconductor element via the solder under the lead terminal. However, the solder under the lead terminal with low 0.2% yield strength reduces the stress that is applied to the semiconductor element. Thus, the reliability of a surface electrode of the semiconductor element that is bonded to the solder under the lead terminal is improved.